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A Novel RF SOI LDMOS with a Raised Drift Region
Available online at www.sciencedirect.com Available online at www.sciencedirect.com
Procedia Engineering
Procedia Engineering 00 (2011) 000–000 Procedia Engineering 29 (2012) 668 – 672 www.elsevier.com/locate/procedia
2012 International Workshop on Information and Electronics Engineering (IWIEE 2012)
A Novel RF SOI LDMOS with a Raised Drift Region Qin Xua, Yufeng Guoa*, Ying Zhanga, Leilei Liua, Jiafei Yaoa, Gene Sheub a
College of Electronic Science and Engineering, Nanjing University of Posts and Telecommunications, Nanjing 210003, China b Department of Computer Science & Information Engineering, Asia University, Taichung, Taiwan 41354, China
Abstract In this paper, we propose a novel RF SOI LDMOS with a raised drift region (RDR). Using the process simulation and numerical simulation, we investigate deeply on breakdown characteristics and frequency characteristics of this novel device. Compared with the conventional RESURF device, the breakdown voltage and cutoff frequency of the RDR device are increased by 25% and 21%, respectively. The work of this paper has theoretical and practical significations to the research of a new generation of deep sub-micron high-performance radio frequency SOI integrated circuits.
© 2011 Published by Elsevier Ltd. Keywords: RF; SOI LDMOS; Raised Drift Region; breakdown voltage; cutoff frequency
1. Introduction Laterally double diffused metal oxide semiconductor (LDMOS) technology is one of the most attractive technologies deployed in RF power amplifier applications because of its ease in integration to standard CMOS technology, high input impedance at high drive current and thermal stability [1]. Especially, silicon on insulator (SOI) LDMOS is more attractive due to its inherent dielectric isolation, high frequency performance and reduced parasitic capacitance [2]. In recent years, many researches focus on optimizing structures to improve breakdown voltage, reduce on-resistance and increase cutoff frequency and maximum oscillation frequency [3-7]. In this paper, we propose a novel RF SOI LDMOS device with an RDR (Raised Drift Region) to improve breakdown characteristics and frequency characteristics. This novel device can be fabricated by using the deep sub-micron CMOS compatible process with an additional LOCOS process to form the
* Corresponding author. Tel.: +86-025-85866321; fax: +86-025-85866321. E-mail address: [email protected].
1877-7058 © 2011 Published by Elsevier Ltd. doi:10.1016/j.proeng.2012.01.021
2
Qin Xu etname al. / Procedia – 672 Author / ProcediaEngineering Engineering2900(2012) (2011)668 000–000
raised drift region. The paper is organized as follows. In section II, the concept of the RDR structure and its fabrication process is proposed. In section III, the breakdown characteristics and frequency characteristics of the RDR device is investigated compared with the conventional RESURF device. Section IV gives a summary of conclusions. 2. Device structure and process A cross section of the RDR RF SOI LDMOS structure is shown in fig. 1(a). In comparison with the conventional RESURF device, the RDR device has a special drift region with the vertical thickness increasing gradually from the source side to the drain side.
Fig. 1. The RDR RF SOI LDMOS device: (a) cross section; (b)-(e) process steps.
Fig. 1(b)-(e) shows the process flow of the RDR device. The proposed process of the RDR device is simulated with 2D process simulator Tsuprem4. The doping concentration of the n-type SOI wafer is 1×1016cm-3. First, LOCOS process is used to fabricate the raised drift region. The oxidation steps are carried out in wet O2 ambient at 1000°C for 97 min, as shown in fig. 1(c). Then, a boron implantation of 3×1013cm-2 dose and 15KeV energy is diffused to form the p-well which is diffused for 10 min at 1000°C. The gate oxide and the poly silicon gate are deposited and etched as shown in fig. 1(d). An arsenic implantation of 2×1015cm-2 dose and 25KeV energy is used to create the source and drain regions. Finally, the field oxide is deposited and the metal contact holes were fabricated as shown in fig. 1(e). 3. Simulation results and discussion 2D device simulator MEDICI is employed to investigate the characteristics of the proposed RDR device and conventional RESURF device with same physical dimensions. Table 1 gives the basic geometric parameters of these devices. Table 1. Device parameters used in simulation.
669
670
Qinname Xu et/ al. / Procedia Engineering 29 (2012) 668 – 672 Author Procedia Engineering 00 (2011) 000–000 Device parameters
Parameter values
Gate oxide thickness (tgox)
65nm
Silicon thickness near the source side (tss)
0.1μm
Silicon thickness near the drain side (tsd)
0.5μm
Buried oxide thickness (tbox)
0.4μm
Gate length (Lgate)
0.18μm
Drift region length (Ld)
1μm
3
3.1. Breakdown characteristics
RDR CONV
21 19 17
Electric fields (10 -5V•cm-1)
Breakdown Voltage(V)
Fig. 2(a) shows the breakdown voltage as a function of the drift doping dose for the RDR and conventional devices. The breakdown voltage of both devices first increases slowly then falls rapidly with the increase of the drift region’s dose. The maximum breakdown voltage of the RDR structure is 19.9V, increased by 25% compared with the conventional device. To further explore the breakdown mechanism of the RDR device, fig. 2(b) gives the surface electric field of both devices when the breakdown voltage is maximized. For the conventional RESURF device, the surface electric field is highest near both ends of the drift region while it is minimal on the central part of the drift region. On the contrary, the RDR structure provides a more uniform surface electric field. The reason is that the RDR device optimizes the surface charge density to be close to the linear distribution, which is very favorable to increase the horizontal breakdown voltage as in VLD devices [8]. Furthermore, an obvious reduction in the electric field peak of P-well/N-drift and N-drift/N+-drain junctions can be seen in the fig. 2(b). 3
RDR
2.5
CONV
2
1.5
15 13
1
0.5
11 0
2 4 6 8 Doping Dose(×1012cm-2)
10
(a)
0 0
0.5 1 Distance along the surface (μm) (b)
Fig. 2. Comparison of the conventional and RDR device: (a) breakdown voltages; (b) surface electric fields of the drift region.
Fig. 3. Equipotential lines (ΔV = 0.5V) for (a) the conventional device; (b) the RDR device.
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Qin Xu etname al. / Procedia – 672 Author / ProcediaEngineering Engineering2900(2012) (2011)668 000–000
4
As shown in fig .3, the P-well/N-drift junction of the RDR device is a negative bevel compared with the conventional RESURF device. Since the negative bevel removes more charge from the P-side of the junction than the N-side, the depletion region expands on the P-side and contracts on the N-side at the surface, which could cause a reduction of the surface electric field [8]. 3.2. Frequency characteristics
2
RDR
Cgd (×10-15F/μm)
Cgs (×10-15F/μm)
For RF LDMOS devices, the gate-source capacitance Cgs and gate-drain capacitance Cgd are the most relevant intrinsic capacitances affecting the cutoff frequency [9]. Fig .4 illustrates t Cgs and Cgd as a function of the drain voltage for the RDR and conventional devices. Cgs of the RDR device is smaller than the conventional one by 10% in the Fig .4(a). However, Cgd of the RDR device increases 23% compared with the conventional one. The reason is that the negative bevel P-well/N-drift junction in the RDR device leads to a smaller depletion width in the drift region [8].
CONV
1.5 1 0.5 0 0
0.5
1 Vgs (V)
1.5
2
RDR
2
CONV
1.5 1 0.5 0 0
(a)
0.5
1 Vgs (V)
1.5
2
(b)
Fig. 4. Simulation results for capacitance comparison between RDR and conventional devices using the small signal method, at frequency 1MHz and Vds = 7V: (a) gate-drain capacitance; (b) gate-source capacitance.
2
RDR
20
RDR
CONV
15
CONV
1.5
Ft / GHz
Gm (×10-4 s/μm)
2.5
10
1
0.5
5 0
0 0
0.5
1 Vgs (V)
1.5
2
(a)
0
0.5
1 Vgs / V
1.5
2
(b)
Fig. 5. Comparison of conventional and RDR devices at frequency 1MHz and Vds = 7V: (a) transconductance; (b) cutoff frequency.
Although suffering from an intrinsic draw back of higher Cgd, the RDR device poses superior transconductance characteristics compared with the conventional device. As shown in fig .5(a), the transconductance of the RDR device increases 33% compared with the conventional one because the novel device can effectively adjust the electric field distribution of the drift region. One of the figures of
672
Qinname Xu et/ al. / Procedia Engineering 29 (2012) 668 – 672 Author Procedia Engineering 00 (2011) 000–000
merit of a RF power device is the cutoff frequency in high-frequency operation. It is defined by the frequency at which the input current becomes equal to the load current [10]. Fig .5(b) shows the simulation results of the comparison between the cutoff frequency and gate voltage for the RDR and conventional devices at Vds=7V. The cutoff frequency of the RDR device is 18.6GHz and increases 21% compared with the conventional one. Thanks to the superior transconductance characteristics, the RDR structure still has the comparable frequency performance in despite of the higher Cgd. 4. Conclusions This paper proposes a novel RF SOI LDMOS device with a Raised Drift Region that can be fabricated by an additional LOCOS process in the deep sub-micro CMOS process. The 0.18µm gate length promises a record cutoff frequency of 18.6GHz and a high breakdown voltage of 19.9V. According to the numerical simulation results by TSUPREM4 and MEDICI, the proposed device is demonstrated to exhibit improved breakdown voltage (by 25%) and cutoff frequency (by 21%) compared to the conventional RESURF device. Therefore, the proposed RDR device is a promising candidate in the area of RF integrated circuits. Acknowledgements We thank the financial support by National Natural Science Funds of China (No. 60806027, No. 61076073), Foundation of Jiangsu Educational Committee (No. 09KJB510010) and State Key Laboratory Funds of Electronic Thin Films and Integrated Devices (No. KFJJ201011). References [1] Jingshun Hai, Zhaohe Hai, Zhengsheng Han. Study on power characteristics of deep sub-micron SOI RF LDMOS. Acta Physica Sinica, 2011, Vol. 60, No.1, p.018501-1–018501-6. [2] M. M. De Souza. Design for Reliability: The RF Power LDMOSFET. IEEE Transactions on Device and Material Reliability; 2007, Vol. 7, No. 1, p. 162–174. [3] Radhakrishnan Sithanandam, M. Jagadesh Kumar. A new Hetero-material Stepped Gate (HSG) SOI LDMOS for RF Power Amplifier Applications. In 23rd International Conference on VLSI Design, Bangalore; 2010, p. 230–234. [4] S. G. Xu, H. P. Zhang, D.J. Wang, et al. Forward Block characteristic of a novel RF SOI LDMOS with a Buried P-type layer. IEEE International SOI Conference, San Diego, USA; 2010. [5] T. Khan, V. Khemka, R. Zhu. Incremental FRESURF LDMOSFET structure for enhanced voltage blocking capability on 0.13um, SOI based technology. In 20th International Symposium on Power Semiconductor Devices and IC's, Oralando; 2008, p. 279–182. [6] H. P. Zhang, L. F. Jiang, L. L. Sun, et al. A Novel SOI LDMOS with a Trench Gate and Field Plate and Trench Drain for RF Applications. International Symposium on Communications and Information Technologies, Laos; 2007, p.34–39. [7] Y. F. Guo, Zhigong Wang, Gene Sheu. Variation of Lateral Thickness Techniques in SOl Lateral High Voltage Transistors. Circuits and Systems (ICCCAS 2009), California; 2009, p.611–613. [8] B. Jayant Baliga. Fundamentals of Power Semiconductor Devices. USA: Springer; 2008, p.144–145. [9] Jaejune Jang, O. Tornblad, et al. RF LDMOS Characterization and Compact Modeling. IEEE MTT-S International, 2001, p. 967–970. [10] F. L. Chang, M. J. Lin, G.Y.Lee, et al. Modeling and design of the high performance step SOl-LIGHT power devices by partition mid-point method. Solid-State Electronics, 2003, Vol. 47, No.10, p.1693–1698.
5
Procedia Engineering
Procedia Engineering 00 (2011) 000–000 Procedia Engineering 29 (2012) 668 – 672 www.elsevier.com/locate/procedia
2012 International Workshop on Information and Electronics Engineering (IWIEE 2012)
A Novel RF SOI LDMOS with a Raised Drift Region Qin Xua, Yufeng Guoa*, Ying Zhanga, Leilei Liua, Jiafei Yaoa, Gene Sheub a
College of Electronic Science and Engineering, Nanjing University of Posts and Telecommunications, Nanjing 210003, China b Department of Computer Science & Information Engineering, Asia University, Taichung, Taiwan 41354, China
Abstract In this paper, we propose a novel RF SOI LDMOS with a raised drift region (RDR). Using the process simulation and numerical simulation, we investigate deeply on breakdown characteristics and frequency characteristics of this novel device. Compared with the conventional RESURF device, the breakdown voltage and cutoff frequency of the RDR device are increased by 25% and 21%, respectively. The work of this paper has theoretical and practical significations to the research of a new generation of deep sub-micron high-performance radio frequency SOI integrated circuits.
© 2011 Published by Elsevier Ltd. Keywords: RF; SOI LDMOS; Raised Drift Region; breakdown voltage; cutoff frequency
1. Introduction Laterally double diffused metal oxide semiconductor (LDMOS) technology is one of the most attractive technologies deployed in RF power amplifier applications because of its ease in integration to standard CMOS technology, high input impedance at high drive current and thermal stability [1]. Especially, silicon on insulator (SOI) LDMOS is more attractive due to its inherent dielectric isolation, high frequency performance and reduced parasitic capacitance [2]. In recent years, many researches focus on optimizing structures to improve breakdown voltage, reduce on-resistance and increase cutoff frequency and maximum oscillation frequency [3-7]. In this paper, we propose a novel RF SOI LDMOS device with an RDR (Raised Drift Region) to improve breakdown characteristics and frequency characteristics. This novel device can be fabricated by using the deep sub-micron CMOS compatible process with an additional LOCOS process to form the
* Corresponding author. Tel.: +86-025-85866321; fax: +86-025-85866321. E-mail address: [email protected].
1877-7058 © 2011 Published by Elsevier Ltd. doi:10.1016/j.proeng.2012.01.021
2
Qin Xu etname al. / Procedia – 672 Author / ProcediaEngineering Engineering2900(2012) (2011)668 000–000
raised drift region. The paper is organized as follows. In section II, the concept of the RDR structure and its fabrication process is proposed. In section III, the breakdown characteristics and frequency characteristics of the RDR device is investigated compared with the conventional RESURF device. Section IV gives a summary of conclusions. 2. Device structure and process A cross section of the RDR RF SOI LDMOS structure is shown in fig. 1(a). In comparison with the conventional RESURF device, the RDR device has a special drift region with the vertical thickness increasing gradually from the source side to the drain side.
Fig. 1. The RDR RF SOI LDMOS device: (a) cross section; (b)-(e) process steps.
Fig. 1(b)-(e) shows the process flow of the RDR device. The proposed process of the RDR device is simulated with 2D process simulator Tsuprem4. The doping concentration of the n-type SOI wafer is 1×1016cm-3. First, LOCOS process is used to fabricate the raised drift region. The oxidation steps are carried out in wet O2 ambient at 1000°C for 97 min, as shown in fig. 1(c). Then, a boron implantation of 3×1013cm-2 dose and 15KeV energy is diffused to form the p-well which is diffused for 10 min at 1000°C. The gate oxide and the poly silicon gate are deposited and etched as shown in fig. 1(d). An arsenic implantation of 2×1015cm-2 dose and 25KeV energy is used to create the source and drain regions. Finally, the field oxide is deposited and the metal contact holes were fabricated as shown in fig. 1(e). 3. Simulation results and discussion 2D device simulator MEDICI is employed to investigate the characteristics of the proposed RDR device and conventional RESURF device with same physical dimensions. Table 1 gives the basic geometric parameters of these devices. Table 1. Device parameters used in simulation.
669
670
Qinname Xu et/ al. / Procedia Engineering 29 (2012) 668 – 672 Author Procedia Engineering 00 (2011) 000–000 Device parameters
Parameter values
Gate oxide thickness (tgox)
65nm
Silicon thickness near the source side (tss)
0.1μm
Silicon thickness near the drain side (tsd)
0.5μm
Buried oxide thickness (tbox)
0.4μm
Gate length (Lgate)
0.18μm
Drift region length (Ld)
1μm
3
3.1. Breakdown characteristics
RDR CONV
21 19 17
Electric fields (10 -5V•cm-1)
Breakdown Voltage(V)
Fig. 2(a) shows the breakdown voltage as a function of the drift doping dose for the RDR and conventional devices. The breakdown voltage of both devices first increases slowly then falls rapidly with the increase of the drift region’s dose. The maximum breakdown voltage of the RDR structure is 19.9V, increased by 25% compared with the conventional device. To further explore the breakdown mechanism of the RDR device, fig. 2(b) gives the surface electric field of both devices when the breakdown voltage is maximized. For the conventional RESURF device, the surface electric field is highest near both ends of the drift region while it is minimal on the central part of the drift region. On the contrary, the RDR structure provides a more uniform surface electric field. The reason is that the RDR device optimizes the surface charge density to be close to the linear distribution, which is very favorable to increase the horizontal breakdown voltage as in VLD devices [8]. Furthermore, an obvious reduction in the electric field peak of P-well/N-drift and N-drift/N+-drain junctions can be seen in the fig. 2(b). 3
RDR
2.5
CONV
2
1.5
15 13
1
0.5
11 0
2 4 6 8 Doping Dose(×1012cm-2)
10
(a)
0 0
0.5 1 Distance along the surface (μm) (b)
Fig. 2. Comparison of the conventional and RDR device: (a) breakdown voltages; (b) surface electric fields of the drift region.
Fig. 3. Equipotential lines (ΔV = 0.5V) for (a) the conventional device; (b) the RDR device.
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Qin Xu etname al. / Procedia – 672 Author / ProcediaEngineering Engineering2900(2012) (2011)668 000–000
4
As shown in fig .3, the P-well/N-drift junction of the RDR device is a negative bevel compared with the conventional RESURF device. Since the negative bevel removes more charge from the P-side of the junction than the N-side, the depletion region expands on the P-side and contracts on the N-side at the surface, which could cause a reduction of the surface electric field [8]. 3.2. Frequency characteristics
2
RDR
Cgd (×10-15F/μm)
Cgs (×10-15F/μm)
For RF LDMOS devices, the gate-source capacitance Cgs and gate-drain capacitance Cgd are the most relevant intrinsic capacitances affecting the cutoff frequency [9]. Fig .4 illustrates t Cgs and Cgd as a function of the drain voltage for the RDR and conventional devices. Cgs of the RDR device is smaller than the conventional one by 10% in the Fig .4(a). However, Cgd of the RDR device increases 23% compared with the conventional one. The reason is that the negative bevel P-well/N-drift junction in the RDR device leads to a smaller depletion width in the drift region [8].
CONV
1.5 1 0.5 0 0
0.5
1 Vgs (V)
1.5
2
RDR
2
CONV
1.5 1 0.5 0 0
(a)
0.5
1 Vgs (V)
1.5
2
(b)
Fig. 4. Simulation results for capacitance comparison between RDR and conventional devices using the small signal method, at frequency 1MHz and Vds = 7V: (a) gate-drain capacitance; (b) gate-source capacitance.
2
RDR
20
RDR
CONV
15
CONV
1.5
Ft / GHz
Gm (×10-4 s/μm)
2.5
10
1
0.5
5 0
0 0
0.5
1 Vgs (V)
1.5
2
(a)
0
0.5
1 Vgs / V
1.5
2
(b)
Fig. 5. Comparison of conventional and RDR devices at frequency 1MHz and Vds = 7V: (a) transconductance; (b) cutoff frequency.
Although suffering from an intrinsic draw back of higher Cgd, the RDR device poses superior transconductance characteristics compared with the conventional device. As shown in fig .5(a), the transconductance of the RDR device increases 33% compared with the conventional one because the novel device can effectively adjust the electric field distribution of the drift region. One of the figures of
672
Qinname Xu et/ al. / Procedia Engineering 29 (2012) 668 – 672 Author Procedia Engineering 00 (2011) 000–000
merit of a RF power device is the cutoff frequency in high-frequency operation. It is defined by the frequency at which the input current becomes equal to the load current [10]. Fig .5(b) shows the simulation results of the comparison between the cutoff frequency and gate voltage for the RDR and conventional devices at Vds=7V. The cutoff frequency of the RDR device is 18.6GHz and increases 21% compared with the conventional one. Thanks to the superior transconductance characteristics, the RDR structure still has the comparable frequency performance in despite of the higher Cgd. 4. Conclusions This paper proposes a novel RF SOI LDMOS device with a Raised Drift Region that can be fabricated by an additional LOCOS process in the deep sub-micro CMOS process. The 0.18µm gate length promises a record cutoff frequency of 18.6GHz and a high breakdown voltage of 19.9V. According to the numerical simulation results by TSUPREM4 and MEDICI, the proposed device is demonstrated to exhibit improved breakdown voltage (by 25%) and cutoff frequency (by 21%) compared to the conventional RESURF device. Therefore, the proposed RDR device is a promising candidate in the area of RF integrated circuits. Acknowledgements We thank the financial support by National Natural Science Funds of China (No. 60806027, No. 61076073), Foundation of Jiangsu Educational Committee (No. 09KJB510010) and State Key Laboratory Funds of Electronic Thin Films and Integrated Devices (No. KFJJ201011). References [1] Jingshun Hai, Zhaohe Hai, Zhengsheng Han. Study on power characteristics of deep sub-micron SOI RF LDMOS. Acta Physica Sinica, 2011, Vol. 60, No.1, p.018501-1–018501-6. [2] M. M. De Souza. Design for Reliability: The RF Power LDMOSFET. IEEE Transactions on Device and Material Reliability; 2007, Vol. 7, No. 1, p. 162–174. [3] Radhakrishnan Sithanandam, M. Jagadesh Kumar. A new Hetero-material Stepped Gate (HSG) SOI LDMOS for RF Power Amplifier Applications. In 23rd International Conference on VLSI Design, Bangalore; 2010, p. 230–234. [4] S. G. Xu, H. P. Zhang, D.J. Wang, et al. Forward Block characteristic of a novel RF SOI LDMOS with a Buried P-type layer. IEEE International SOI Conference, San Diego, USA; 2010. [5] T. Khan, V. Khemka, R. Zhu. Incremental FRESURF LDMOSFET structure for enhanced voltage blocking capability on 0.13um, SOI based technology. In 20th International Symposium on Power Semiconductor Devices and IC's, Oralando; 2008, p. 279–182. [6] H. P. Zhang, L. F. Jiang, L. L. Sun, et al. A Novel SOI LDMOS with a Trench Gate and Field Plate and Trench Drain for RF Applications. International Symposium on Communications and Information Technologies, Laos; 2007, p.34–39. [7] Y. F. Guo, Zhigong Wang, Gene Sheu. Variation of Lateral Thickness Techniques in SOl Lateral High Voltage Transistors. Circuits and Systems (ICCCAS 2009), California; 2009, p.611–613. [8] B. Jayant Baliga. Fundamentals of Power Semiconductor Devices. USA: Springer; 2008, p.144–145. [9] Jaejune Jang, O. Tornblad, et al. RF LDMOS Characterization and Compact Modeling. IEEE MTT-S International, 2001, p. 967–970. [10] F. L. Chang, M. J. Lin, G.Y.Lee, et al. Modeling and design of the high performance step SOl-LIGHT power devices by partition mid-point method. Solid-State Electronics, 2003, Vol. 47, No.10, p.1693–1698.
5